A radio-frequency power amplifier (RF power amplifier) is a type of electronic amplifier that converts a low-power radio-frequency (RF) signal into a higher-power signal.[1] Typically, RF power amplifiers are used in the final stage of a radio transmitter, their output driving the antenna. Design goals often include gain, power output, bandwidth, power efficiency, linearity (low signal compression at rated output), input and output impedance matching, and heat dissipation.
Amplifier classes
RF amplifier circuits operate in different modes, called "classes", based on how much of the cycle of the sinusoidal radio signal the amplifier (transistor or vacuum tube) is conducting current. Some classes are class A, class AB, class B, which are considered the linear amplifier classes in which the active device is used as a controlled current source, while class C is a nonlinear class in which the active device is used as a switch. The bias at the input of the active device determines the class of the amplifier.
A common trade-off in power amplifier design is the trade-off between efficiency and linearity. The previously named classes become more efficient, but less linear, in the order they are listed. Operating the active device as a switch results in higher efficiency, theoretically up to 100%, but lower linearity.[2] Among the switch-mode classes are class D, class F and class E.[3] The class D amplifier is not often used in RF applications because the finite switching speed of the active devices and possible charge storage in saturation could lead to a large I-V product,[2] which deteriorates efficiency.
Solid state vs. vacuum tube amplifiers
Modern RF power amplifiers use solid-state devices, predominantly MOSFETs (metal–oxide–semiconductor field-effect transistors).[4][5][6] The earliest MOSFET-based RF amplifiers date back to the mid-1960s.[7] Bipolar junction transistors were also commonly used in the past, up until they were replaced by power MOSFETs, particularly LDMOS transistors, as the standard technology for RF power amplifiers by the 1990s,[4][6] due to the superior RF performance of LDMOS transistors.[6] Generally speaking, solid-state power amplifiers contain four main components: input, output, amplification stage and power supply.[8]
MOSFET transistors and other modern solid-state devices have replaced vacuum tubes in most electronic devices, but tubes are still used in some high-power transmitters (see Valve RF amplifier). Although mechanically robust, transistors are electrically fragile – they are easily damaged by excess voltage or current. Tubes are mechanically fragile but electrically robust – they can handle remarkably high electrical overloads without appreciable damage.
Applications
The basic applications of the RF power amplifier include driving to another high-power source, driving a transmitting antenna and exciting microwave cavity resonators. Among these applications, driving transmitter antennas is most well known. The transmitter–receivers are used not only for voice and data communication but also for weather sensing (in the form of a radar).
RF power amplifiers using LDMOS (laterally diffused MOSFET) are the most widely used power semiconductor devices in wireless telecommunication networks, particularly mobile networks.[4][9][6] LDMOS-based RF power amplifiers are widely used in digital mobile networks such as 2G, 3G,[4][6] and 4G[9] and the good cost/performance ratio make them the preferred option for amateur radio.[10]
Wideband amplifier design
Impedance transformations over large bandwidth are difficult to realize, so conventionally, most wideband amplifiers are designed to feed a 50 Ω output load. Transistor output power is then limited to
where
- is defined as the breakdown voltage,
- is defined as the knee voltage,
- is chosen so that the rated power can be met.
The external load is, by convention, Therefore, there must be some sort of impedance matching that transforms from to
The loadline method is often used in RF power amplifier design.[11]
See also
References
- ↑ "RF Amplifiers". info.apitech.com. Retrieved 18 May 2021.
- 1 2 Lee, Thomas (2003). The Design of CMOS Radio-Frequency Integrated Circuits. Cambridge, UK: Cambridge University Press. pp. 494–503.
- ↑
Cloutier, Stephen R. (WA1QIX). "Class E, AM transmitter descriptions, circuits, etc". www.classeradio.com. WA1QIX. Retrieved 6 June 2015 – via qrz.com.
{{cite web}}
: CS1 maint: numeric names: authors list (link) - 1 2 3 4 Baliga, B. Jayant (2005). Silicon RF Power MOSFETs. World Scientific. p. 1. ISBN 9789812561213.
- ↑ "Ameritron ALS-1300: 1200 Watt no-tune TMOS-FET amplifier". product information downloads. MFJ Enterprises. Archived from the original on 23 April 2014. Retrieved 6 June 2015.
- 1 2 3 4 5 Perugupalli, Prasanth; Leighton, Larry; Johansson, Jan; Chen, Qiang (2001). "LDMOS RF power transistors and their applications" (PDF). In Dye, Norman; Granberg, Helge (eds.). Radio Frequency Transistors: Principles and practical applications. Elsevier. pp. 259–92. ISBN 9780080497945.
- ↑ Austin, W. M.; Dean, J. A.; Griswold, D. M.; Hart, O. P. (November 1966). "TV Applications of MOS Transistors". IEEE Transactions on Broadcast and Television Receivers. 12 (4): 68–76. doi:10.1109/TBTR1.1966.4320029.
- ↑ UTE I. VON MEHLEM, ROBERT E. WALLIS (1989). "SOLID-STATE POWER AMPLIFIERS FOR SATELLITE RADAR ALTIMETERS" (PDF). Johns Hopkins University.
- 1 2 Asif, Saad (2018). 5G Mobile Communications: Concepts and Technologies. CRC Press. p. 134. ISBN 9780429881343.
- ↑ "A 600W broadband HF/6m amplifier using affordable LDMOS devices". 27 October 2019.
- ↑ Ozalas, Matthew (14 January 2015). How to design an RF power amplifier – the basics (short how-to video). Retrieved 10 February 2015 – via youtube.com.
External links
- Fuentes, Carlos (October 2008). Microwave Power Amplifier Fundamentals (PDF) (Report). Bern, Switzerland: European Centre for Nuclear Research. Retrieved 5 March 2013.
- Khanifar, Ahmad (1 December 2014). "Wideband RF Power Amplifier Design Guidelines / RF Power Amplifier Design for Digital Predistortion". linamptech.com. Technical support. Laguna Hills, CA: Linamp Technologies, Inc. Retrieved 1 December 2014.